Modeling, simulation and control of a doubly-fed induction generator for wind energy conversion systems

International Journal of Power Electronics and Drive System (IJPEDS)
Vol. 11, No. 3, September 2020, pp. 1197~1210
ISSN: 2088-8694, DOI: 10.11591/ijpeds.v11.i3.pp1197-1210  1197
Journal homepage: http://ijpeds.iaescore.com
Modeling, simulation and control of a doubly-fed induction
generator for wind energy conversion systems
Boumerid Bensahila Med El Amine1
, Allali Ahmed2
, Merabet Boulouiha Houari3
, Denai Mouloud4
1,2,3
Faculty of Electrical Engineering, University of Sciences and Technology of Oran Med Boudiaf, Algeria
3
Ecole Nationale Polytechnique of Oran, Algeria
4
University of Hertfordshire, United Kingdom
Article Info ABSTRACT
Article history:
Received Mar 16, 2019
Revised Jul 8, 2019
Accepted Apr 9, 2020
In recent years, wind energy has become one of the most promising
renewable energy sources. Various wind turbine concepts with different
generator topologies have been developed to convert this abundant energy
into electric power. The doubly-fed induction generator (DFIG) is currently
the most common type of generator used in wind farms. Usually the DFIG
generator is a wound rotor induction machine, where the stator circuit is
directly connected to grid while the rotor’s winding is connected to the grid
via a three-phase converter. This paper describes an approach for the
independent control of the active and reactive powers of the variable-speed
DFIG. The simulation model including a 1.5 MW-DFIG driven by a wind
turbine, a PWM back-to-back inverter and the proposed control strategy are
developed and implemented using MATLAB/Simulink/SimPowerSystems
environment.
Keywords:
DFIG
MPPT
PWM
SimPowerSystems
Simulink
Wind energy This is an open access article under the CC BY-SA license.
Corresponding Author:
Allali Ahmed,
Département de Génie Electrique, Faculté de l’électrotechnique,
Faculty of Electrical Engineering, University of Sciences and Technology of Oran Med Boudiaf, Algeria.
Email: allalia@yahoo.com
1. INTRODUCTION
In the last decade, interest in wind energy use has grown considerably. In Europe 30-40% of newly
installed renewable energy capacity was from wind power [1]. The U.S and China are currently the world
leaders and dominate the global installed wind energy [2, 3]. In 2010, the world’s generation capacity from
wind energy was 196.630 GW and reached 240 GW by the end of 2011 [4].
With the expansion of this renewable energy resource and its increased penetration into the
electrical grids, wind turbine (WT) technology is currently one of the world’s fastest growing, cost-effective
renewable energy technologies in the market [5].
Wind power generation is subject to fluctuations due to the intermittent nature of wind energy and
wind speed variations. This is more evident when multiple generators are connected to a weak grid [6].
Many topologies for wind turbines have been designed to reduce the fluctuations of the output
power. Doubly-fed induction generators (DFIG) are the most widely used types of generators in wind energy
conversion systems. This topology can offset its output power to stabilize fluctuations by a factor of typically
up to ± 30%. However, this device is still small considering the range of variation in practice of the wind
speed. Researchers have proposed that energy storage systems are a desirable choice to further mitigate the
effects of short-term wind fluctuations [5, 6].
Fixed-speed induction generators are constrained to operate near the synchronous speed, because the
frequency is imposed by the network; the rotor speed is almost constant. Variable-speed wind turbine

 ISSN: 2088-8694
Int J Pow Elec & Dri Syst, Vol. 11, No. 3, September 2020 : 1197 – 1210
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systems, on the other hand, are able to operate over a wide range of wind speeds. Furthermore, using an
appropriate maximum power point tracking (MPPT) strategy, variable-speed wind turbines can produce
maximum power at varying wind speed conditions. For variable-speed wind turbine systems with limited
speed range, e.g. ± 30% of synchronous speed, the DFIG can be the solution of choice [7].
Unlike conventional wind turbine-driven synchronous generators, the output characteristic of the
variable-speed wind energy conversion systems (WECS) depends not only on the dynamics of the generator
but also on the converter control strategy employed. Control strategies of DFIG have been extensively
discussed by several authors [8, 9]. In [10], various control mechanisms for the DFIG have been reported
using stator flux orientation in the reference frame α-β. In [11] and [12], the stator flux oriented control of the
generator DFIG has been studied but without any control of the grid side and DC link voltages. In [13], the
authors studied the effect of active and reactive powers variations by a decoupling control method for the
active and reactive powers. However, the influence of different load types on the grid and power quality
according to the loads connected to the generator DFIG has not been addressed. This paper presents a
comprehensive simulation study of the variations of reactive power on the grid under different load
conditions (resistive, inductive and capacitive) and analyses the influence of these loads on the DFIG power
factor which reflects the quality of the power generated.
The main advantage of using DFIGs in wind turbines is that they connect directly to the network via
the three-phase stator windings and do not require additional converters. This configuration has become now
very popular for variable-speed wind turbines [14]. This is mainly because the power electronic converter
must handle only a fraction of 20% to 30% of the total power generated by the DFIG [14, 15]. Therefore, the
losses in the power electronic converter can be reduced. Today, the DFIG is the most commonly used
variable-speed machine in production units above 1 MW.
This paper presents a study of a DFIG dual-powered generator connected with industrial loads to
learn the impact on the quality of voltage and current by applying inductive or capacitive loads.
The aim of this paper is to design an indirect vector control decoupling strategy to achieve
independent control of the active and reactive powers of the DFIG-WT conversion system. A detailed model
of the DFIG is used to design and evaluate the proposed control strategies. The authors present a technique of
the stator quadrature flux along the axis to control the active and reactive powers of the DFIG. The proposed
control approach is evaluated under resistive, inductive and capacitive loads connected between the DFIG
and the grid.
The rest of the paper is organized as follows: Section 2 introduces the overall simulation model
structure including mathematical models of the wind turbine. The proposed MPPT method used in the model
is also presented. Section 3 of the paper presents the model of the DFIG and its indirect vector control
scheme using Park transformation, the control of the DC side voltage. Finally, the simulation results and
conclusions are summarized in Section 4 and 5 respectively.
2. PROPOSED WIND ENERGY CONVERSION SYSTEM MODEL
The proposed circuit is shown in Figure1. It consists of a three-blade wind turbine connected to a
variable-speed DFIG. The stator circuit of the DFIG is directly connected to the grid, whereas the rotor
winding is connected to the grid via two PWM-controlled IGBT-converters. The two converters are coupled
through a DC link capacitor.
The rotor-side converter controls simultaneously the active and reactive powers by adjusting the
amplitude, frequency and phase of the rotor voltages. The aim of the grid-side converter is to regulate the DC
link voltage. The inputs to the control system are the voltages and currents on the source side and the voltage
on the DC side. These quantities are transformed into their d and q components. A phase-locked loop circuit
is used to synchronize the frequency of the system with the network frequency.

Int J Pow Elec & Dri Syst ISSN: 2088-8694 
Modeling, simulation and control of a doubly-fed induction … (Boumerid Bensahila Med El Amine)
1199
Induction
Generator
Wind
Turbine
DC
AC
AC
Rf
Lf
AC/DC/AC converter
Cgrid
Crotor
Ps
Qs
Pm
Control
vrabc vgabc Three phase
Grid
Gearbox
Rotor
Stator
industrial
load
Figure1. Wind turbine with a DFIG
2.1 Modeling the wind turbine with MPPT strategy
The relationship between the wind speed and the aerodynamic mechanical power extracted from the
wind can be described as follows [16, 17]:
2 3
1
. . . ( , ).
2
m p
P R C v
   
=
(1)
Pm: is the mechanical power of the wind turbine [W],
β: is the orientation angle of the blades [°].
The power coefficient Cp defines the aerodynamic efficiency of the wind turbine. It depends on the
characteristic of the turbine and is a function of the speed ratio λ and the orientation angle β of the blade:
( ) ( )
5
2
1 3 4 6
, i
C
p
i
C
C C C C e C

   

−
 
= − − +
 
  (2)
The values used for the coefficients C1 - C6 are given in Table 1 [18]:
Table 1 Coefficients of the turbine
C1 C2 C3 C4 C5 C6
0.5176 116 0.4 5 21 0.0068
With
3
1 1 0.035
0.08 1
i
   
= −
+ +
(3)
λ is defined as the ratio of the linear velocity at the end of the blade and is given by:
m R
v


=
(4)

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It can be observed from Figure 2 that the power coefficient reaches a maximum for a pitch angle of
0° and a particular value λnom = 8.1 of the velocity ratio. The power coefficient value corresponding to
λnom is Cpmax = 0.48.
Figure 2. Characteristic of the power coefficient as a function of λ
Depending on the wind aerodynamic conditions, there exists an optimal operating point which
allows the maximum power to be extracted from the turbine. This can be achieved by either controlling the
rotational speed of the turbine or the power of the turbine. Several MPPT methods can be used either with or
without the knowledge of the wind turbine characteristics [19]. In this study, the first method has been
applied. The optimum rotation Ωm, opt for the mechanical transmission of the maximum wind turbine is
given by [20]:
,
nom
m opt
v
R

 =
(5)
the following relation can be deduced:
3
, max , ,
m p opt m opt
P K
= 
(6)
where:
5
, ,max 3
1
2
p opt p
nom
R
K C


=
(7)
thus, the corresponding optimum torque is:
,max 2
, , ,
,
m
m opt p opt m opt
m opt
P
T K
= = 

(8)
On the power characteristic of a turbine (Figure 3), the locus of the point representing the maximum
power is obtained by adapting the speed of the turbine (thick curve) to that of the wind speed.

1201
Figure 3. The characteristics of system optimum turbine
2.2 Modeling of the DFIG
The Park model of the DFIG is given by the following set of equations [21]:
( )
( )
ds
ds s ds s qs
qs
qs s qs s ds
dr
dr r dr s r qr
qr
qr r qr s r dr
d
v R i
dt
d
v R i
dt
d
v R i
dt
d
v R i
dt

 

 

  

  

= − +



= + +



 = − − +


 = + − +

 (9)
The stator flux equations are:
ds s ds m dr
qs s qs m qr
L i L i
L i L i


= +



= +

 (11)
Similarly, the rotor flux equations are:
dr r dr m ds
qr r qr m qs
L i L i
L i L i


= +



= +

 (12)
In these equations, Rs, Rr, Ls and Lr denote respectively the resistances and inductances of the
stator windings and rotor, Lm is the cyclic mutual inductance, ωr = P.Ωr is the rotor speed (with P the
number of pole pairs) and ωs is the synchronous angular speed. vds, vqs, vdr, vqr, ids, iqs, idr, iqr, øds, øqs,
ødr and øqr are respectively the direct and quadratic components of voltages, currents and fluxes in the stator
and rotor. The active and reactive powers of the stator and rotor are obtained as:
( )
( )
3
. .
2
3
. .
2
s ds ds qs qs
s qs ds ds qs
P v i v i
Q v i v i

= +



 = −

 (13)

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( )
( )
3
. .
2
3
. .
2
r dr dr qr qr
r qr dr dr qr
P v i v i
Q v i v i

= +



 = −

 (14)
The mechanical and electromagnetic torque are given by the following equations:
r
m em r
d
T T J f
dt


= + +
(15)
( )
. .
m
em qs dr ds qr
s
L
T P i i
L
 
= − +
(16)
Where J is the moment of inertia and f is the viscous friction coefficient.
3. CONTROL SCHEME OF THE GENERATOR AND CONVERTERS
3.1. Control of the Rotor Side Converter
The stator flux vector is chosen to be aligned with the q-axis Park reference frame. The grid is
assumed to be stable and therefore øsq is constant. The resistance Rs of the DFIG stator is neglected.
0
ds
ds
qs s
s
v

 

=



= 

 (17)
0
ds s
qs
v V
v
=



=

 (18)
Where Vs represents the r.m.s. value of the grid voltage. The torque (16) becomes:
3
2 2
m
em qs dr
s
L
P
T i
L

= −
(19)
The stator flux equations (11) become:
0 s ds m dr
qs s qs m qr
L i L i
L i L i

= +



= +

 (20)
From (20), the equations linking the stator and rotor currents are:
m
ds dr
s
qs m
qs qr
s s
L
i i
L
L
i i
L L


= −



 = −

 (21)
The active and reactive powers of the DFIG given by (18) are re-written as:

1203
2
3 3
2 2
3 3
2 2
m
s s ds s dr
s
s m s
s s qs rq
s s s
L
P V i V i
L
V L V
Q V i i
L L


= = −



 
 = = −
 
  
 (22)
Then the rotor voltages can be written as:
'
'
m
dr dr slip qs r qr
s
qr qr slip r dr
L
v v L i
L
v v L i
  
 
  
= − +
  
 


= +
 (23)
'
'
dr
dr r dr r
qr
qr r qr r
di
v R i L
dt
di
v R i L
dt



= +



 = +

 (24)
Where the slip angular velocity ωslip, and total leakage coefficient σ are given by:
2
, 1 m
slip s r
s r
L
L L
   
= − = −
The rotor side controller consisting of the active and reactive power controllers is shown in Figure 4.
DFIG
DC link
C
Transformer
Three phase
Grid
encoder
θr
PI
PI
PI
PI
Power
Control
(Slower
Control Loop)
(Fast Control
Loop)
Rotor
Current
Control
abc
dq
isabc
vsabc
PLL
idqs
vdqs
abc
dq
idqr irabc
ωs
d/dt
ωr
ωslip
+
-
+
+
-
-
-
-
+
+
ωslip
P*
Q*
Pmeas
Qmeas
idr*
iqr*
idr
iqr
ωslip σ Lr
idr
ωslip(Lm/Ls.øqs+σLridr)
+
-
+
+
abc
dq
vdr
’
vqr
’
PWM
ωslip
vabcr*
vdr
*
vqr
*
6
Calculate active
and reactive
power based on dq
components
Pmeas
Qmeas
Figure 4. Rotor side controller for the DFIG
3.2 Control of the grid side converter

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The grid side converter can also be used to control the power factor of the system by adding a
control loop for the reactive power via the q-axis current. In the system, the quadratic component of the
reference current is set to zero in order maintain a unity power factor. A similar control strategy was applied
to the grid side converter, since the active and reactive powers of the grid side converter can be controlled
independently by acting on the d and q components of the grid side voltage [5]. The grid side converter
model in Park coordinates system is [22-25]:
1
f
s
f
d d d od
q q q oq
f f
s
f
R
L
i i v v
d
i i v v
R
dt L
L


 
−
 
−
     
 
= +
     
  −
     
 
− −
 
  (25)
Where: Rf and Lf are respectively the resistance and the leakage inductance of the grid-side transformer, vd
and vq are the source voltage components and voq vod are the inverter voltages. Using the decoupling
method by compensation, the inverter voltages can be written as:
1
1
od od od
oq oq oq
v e v
v e v
= −



= −

 (26)
With the control coefficients:
1
1
d
od f
q
oq f
di
v L
dt
di
v L
dt

=



 =

 (27)
And the coefficients of compensation are obtained as:
od f d f s q d
oq f s d f q q
e R i L i v
e L i R i v


= − + +



= − − +

 (28)
Neglecting the converter losses, the DC bus voltage vdc varies with the power exchanged between the
turbine and the network and is given by:
_ _
dc
dc dc rotor dc grille
dv
C I I I
dt
= = −
(29)
The proposed control strategy for the DC link is depicted in Figure 5. It includes two control loops,
an inner loop and an outer loop. The outer loop consists of a proportional and integral (PI) controller for
regulating the DC link voltage. The output of the DC voltage controller represents the d-axis current
reference idref from the source which is then compared with the measured current Idmeas. The quadrature
component of the source current iq is used to control the flow of reactive power. As discussed earlier, the
reactive power reference is set to zero in order to obtain a unity power factor.

1205
DC link
Rf
Lf
Power
network
3
2
3
2
iabc
vabc
ωs
ωs
idq
vdq
vdc*
vdc
PI
DC Voltage control
(Slower Control Loop)
PI
PI
Current control
(Fast Control
Loop)
id*
+
-
PWM
6
+
-
+
-
id
iq
0
ωs
vod1*
voq1*
-Rf.id+Lf.ωs.iq+vd
-Lf.ωs.id-Rf.iq+vq
+
+
+
+
iq*
3
2
vod*
voq*
voabc
*
Figure 5. Controller side of the grid DFIG
4. RESULTS AND DISCUSSION
Figure 6 shows the overall model of the WECS and control scheme implementation in
MATLAB/Simulink/SimPowerSystems. In the following, some simulation tests are presented to illustrate the
performance of the proposed control system for the WECS.
Figure 6. MATLAB/Simulink diagram of DFIG and control scheme

 ISSN: 2088-8694
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The Side Grid Converter (SGC) adjusts the amplitude and frequency of the signal to be sent to the
rotor of the DFIG: It acts on the voltages at the terminals of the rotor circuits. It varies the speed of the
turbine and thus the power extracted.
Figure 7 shows the responses of direct (ird) and quadrature (irq) DFIG rotor currents and the stator
active (Ps) and reactive (Qs) powers. The direct component ird controls the active power Ps. For a nominal
power of Ps = 1.5 MW, the required forward current reaches a value of 1.5 kA. The reactive power Qs is
controlled by the reactive component of current irq. The results show a good tracking performance when the
reactive power reference is stepped from 0 to 0.5MVAR and then -0.5MVAR.
The reactive power supplied to the grid can be controlled by the reactive power generated or
absorbed by the Rotor Side Converter (RSC) connected to the rotor. The reactive power is exchanged
between this converter and the network, through the generator. Indeed, it absorbs reactive power to
compensate for mutual inductances and leakage inductances. The converter connected to the network can
also operate as a reactive power compensator.
It is noted that any variation in the rotor or rotor voltage frequency has a direct influence on the
power and torque.
The quadrature component of the rotor current controls the active power, and the direct component
controls the reactive power exchanged between the stator and the network as shown in Figure 7. It can be
observed that both active and reactive powers of the DFIG follow their references.
The DC link voltage, the amplitude modulation index (MI) and the voltage vra and current ira in
phase A of the rotor are shown in Figure 8. It can be noted that the DC voltage tracks perfectly its reference
of 1.5 kV.
Figure 9 shows the responses of the electromagnetic torque, rotor angular speed, the speed ratio λ
and the power coefficient Cp. The power factor Cp is expected to reach an optimal value of 0.48 after a short
transient while the speed λ reaches only the maximum of 8.1.
Figure 7. Active and reactive powers of stator and
rotor currents
Figure 8. DC link, modulation index (MI), current
and phase A voltage of the rotor
Figure 9. Response of the electromagnetic torque,
rotor angular velocity, tip speed ratio λ and power
coefficient Cp
Figure 10. Active and reactive powers of the stator
and rotor currents (resistive load conditions)

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The DFIG is now connected to resistive, inductive and capacitive loads respectively. The simulation
results shown below are obtained at the same wind speed of 11 m/sec. Figure 10 shows the responses of the
real (Ps) and reactive (Qs) powers of the stator, the real (PL) and reactive (QL) powers of the load and the
resulting currents ird and irq in the case of a resistive load. Note that the grid absorbs the DFIG 1.5 MW
active before the application of the load. After application of a load of 1.5 MW at time t = 1 sec, the power
supplied by the DFIG is then consumed by the load and the power of the grid becomes zero. The results are
illustrated in Figure 11. It can be noted that the voltage vdc follows its reference of 1.5 kV. The grid and load
currents reached their steady-state values of 1.5 kA and 0 A respectively before the application of the load.
After the application of the load, the current of the load becomes 1.5 kA and that of the grid becomes 0 A.
Figure 11. DC link voltage, amplitude modulation
index (MI), phase A current of the grid and load and
the current of DFIG rotor (resistive load conditions)
Figure 12. Active and reactive powers of stator, load
and rotor currents (inductive load conditions)
Figure 12 shows the responses of real and reactive powers of stator (Ps and Qs) and those of the
load (PL and QL) and the responses of the DFIG rotor currents ird and irq for an inductive load (PL =1.5
MW and QL =0.5 MVAR). Note that the grid absorbs the active power generated by the DFIG before
applying the load. After application of the load at the instant t = 1 sec, the necessary power to be consumed
by the load is supplied by the DFIG and the power of the grid becomes zero. The load, the DC link voltage
vdc, modulation index (IM), the currents of the grid and load and the DFIG rotor currents are illustrated in
Figure 13. Similar remarks and conclusions can be drawn as in the case of resistive load.
Figure 13. DC link voltage, amplitude modulation
index (MI), phase A current of the grid and load
and the current of DFIG rotor current (inductive
load conditions)
Figure 14. Active and reactive powers of stator and
load and rotor currents (capacitive load conditions)

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A capacitive load is now introduced (PL = 1.5 MW and QL = 0.5 MVAR) and Figure 14 show the
results. Note that, in this case, the grid absorbs the active power generated by the DFIG before the load is
applied. After application of the load at the instant t = 1 sec, the power supplied by the DFIG is consumed by
the load and the power of the grid becomes zero. Figure 15 shows, the DC link voltage vdc, the modulation
index (IM), the currents of the grid and the load and DFIG rotor currents. Table 2 summarizes the results
obtained with the three types of loads and the effects on the power factor of the DFIG.
Figure 15. DC link voltage, amplitude modulation index (MI), phase A current of the grid and load and the
current of DFIG rotor current (capacitive load conditions)
Table 2 Comparison of the three types of loads.
load active power of DFIG [MW] reactive power of DFIG [MVAR] Power factor cosφDFIG
resistive 1.5 0 1
inductive 1.5 -0.5 0.95 lagging
capacitive 1.5 0.5 0.95 leading
Figure 16 shows the current waveforms of phase A for the three different types of load and the grid
phase A voltage. This figure clearly illustrates that the voltage and the current generated by the DFIG are in-
phase when the load is resistive. The current is lagging and leading the voltage when the load is respectively
inductive and capacitive.
One can say that the shapes of the curves show an acceptable tracking of the stator reactive power.
The same applies to the stator active power and the total reactive power supplied to the network. This method
of control presents remarkable performance in terms of reactive power control in the network through the
wind system. This setting allows us to have a negative reactive power (capacitive behavior) or positive
(inductive behavior) and even zero (unity power factor).
It can be noted that the reactive power that can be generated or absorbed is limited by the level of
the rotor currents, these currents are also imposed by the switches of the IGBT power devices.
Figure 17 shows the waveforms of the instantaneous active power generated by the DFIG under
these three load conditions.
In the case of capacitive load, ripples can be observed in Figure 17 due to the stator voltages of the
DFIG. On the hand, in the case of inductive load, voltage drops appear in the network voltages which caused
a reduction of these ripples in the stator power waveform. In addition, the inductance can filter the line
currents which leads to a significant improvement of the power quality.

1209
Figure 16. Phase A grid voltage and current
waveforms for resistive, inductive and capacitive
loads
Figure 17. DFIG stator active powers for resistive,
inductive and capacitive loads
5. CONCLUSION
This paper presented the modeling, simulation and control of a DFIG based wind conversion system
connected to the grid. The overall system was implemented using MATLAB/Simulink and
SimPowerSystems toolbox. The indirect vector control method is used to control the stator flux and hence the
active and reactive powers of the DFIG. The reference of the active power generated by the DFIG is set
according to the wind speed using a maximum power point tracking (MPPT) strategy. The reactive power
set-point is varied according to the type load connected to the generator. Three types of load scenarios have
been considered (resistive load inductive and capacitive) to demonstrate the influence of the load on the
DFIG. The simulation results show the effectiveness of the decoupling controller and MPPT strategy under
these three load conditions. The grid-connected DFIG simulation model presented in this work can be easily
extended to include other compensating devices such as SVC (Static Var Compensator) or ASVC (Advanced
Static Var Compensator) and can also be used to investigate other more robust control strategies to further
improve the performance of the system in response to grid disturbances.
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